KR100642218B1 - A magnetic field press apparatus - Google Patents

Abstract

  The present invention relates to a magnetic field press method for producing rare earth magnets and a magnetic field press apparatus for vertically and uniformly forming boundary portions of N and S poles formed on both sides of the manufactured rare earth magnet, and solidifying after melting the rare earth alloy. A method of manufacturing a rare earth magnet comprising a step of pulverizing with a powder, followed by a magnetic field pressing step of applying a magnetic field to the powder to pressurize to a constant pressure to produce a magnet molded body, and sintering the magnet molded body; The magnetic field press step includes an inner filling space in which upper and lower openings are filled, and the powder is filled, and an image of a non-magnetic material compressing a mold filled with a magnetic field generating unit and a powder filled in the mold. The process of preparing a lower mold, and filling the powder between the upper and lower molds, and pressing the powder through the upper and lower molds while applying a magnetic field to the powder in the magnetic field generating unit to form a magnet molded body. It is characterized by a magnetic field press method for producing rare earth magnets.

In addition, in the rare earth-based magnet manufacturing apparatus comprising a magnetic field press device for producing a magnetic molded body by applying a magnetic field while pressing the rare earth-based alloy powder to be a raw material of the magnet at a constant pressure, the magnetic field press device is open, upper and lower And a mold frame having a magnetic field generating portion for forming a magnetic field in the direction of the N pole to the S pole on the outside thereof, and a powder filled in the powder filling the inner filling space of the mold. It is characterized by a magnetic field press apparatus for manufacturing rare earth magnets composed of upper and lower molds of a nonmagnetic material that compresses powder while being applied.

Description

Magnetic field press apparatus for manufacturing rare earth magnets {A magnetic field press apparatus}

1 is a cross-sectional view showing a magnetic field press apparatus according to the first embodiment of the present invention.

Figure 2 is a process chart showing a magnet manufacturing method through the magnetic field press apparatus of the first embodiment according to the present invention.

3 shows a magnet completed through the apparatus and process according to the invention.

Figure 4 is a cross-sectional view showing a magnetic field press apparatus according to a second embodiment of the present invention.

Figure 5 is a cross-sectional view showing another embodiment of the magnetic field press apparatus according to the second embodiment of the present invention.

Figure 6 is a cross-sectional view showing a magnetic field press apparatus of one embodiment used in the pressing step of the conventional magnet manufacturing process.

7 is a view showing a magnet manufactured through a conventional magnetic field press apparatus.

<Explanation of symbols for the main parts of the drawings>

1: mold

    11: filling space

2: magnetic field generating unit

    21: N-pole electromagnet

    22: S pole electromagnet

3: phase mold

4: HA mold

5: powder

The present invention relates to a magnetic press device for manufacturing rare earth magnets, and more particularly, to a magnetic press device for manufacturing rare earth magnets such that the boundary portions of the N and S poles formed on both sides of the rare earth magnet are vertically and uniformly formed. It is about.

Generally, rare earth (Nd-Fe-B) magnets are high-performance permanent magnets of iron type, and are anisotropic sintered magnets composed mainly of neodymium (Nd), iron (Fe), and boron (B), and have a tetragonal structure. It is based on liver compounds. Such rare earth magnets have a coercive force ten times higher than that of ordinary magnets and are widely used in calculators and communication devices.

Thus, the manufacturing process of a commonly known rare earth magnet is described as follows.

First, the rare earth (Nd-Fe-B) -based alloy is melted through a melting furnace, and then solidified and molded into an ingot.

Next, the ingots shaped as above are ground into powder (3 ?? m) through a grinding apparatus.

Next, the powder pulverized as described above is put into a mold forming the magnetic field press, and then the magnetic field is applied from the outside to press the powder at a predetermined pressure while maintaining the magnetic alignment to form a magnetic molded body.

Finally, the rare earth magnet is manufactured by sintering by applying heat to the magnet molded body.

Hereinafter, the magnetic press process in the manufacturing process of the magnet as described above in more detail.

Figure 6 shows a magnetic field press apparatus of one embodiment used in the pressing process of the conventional magnet manufacturing process.

Accordingly, the magnetic field press apparatus of the conventional embodiment includes a mold frame 100 including a filling space 101 having upper and lower openings so that powder can be filled therein, and upper and lower portions of the filling space 101. The magnetic field generating unit 500 is provided on the outside of the upper and lower molds 300 and 400 and the mold mold 100 to compress the powder 200 inserted therebetween by being inserted and lowered and raised to apply a magnetic field to the powder. It consists of.

The magnetic field generating unit 500 is composed of N, S-pole electromagnets 501.502 provided on both sides such that a magnetic field is formed in the direction of the N-pole to the S-pole.

Therefore, when a current flows through the N and S pole electromagnets 501 and 502 constituting the magnetic field generating unit 500, the powder compressed in the space therebetween is magnetized under the influence of the magnetic field. Therefore, the side close to the N pole electromagnet 501 is magnetized to the S pole, and the side close to the S pole electromagnet 502 opposite thereto is magnetized to the N pole.

However, in the press process as described above, the upper and lower molds 300 and 400 for compressing the powder filled in the filling space 101 of the mold mold 100 is usually made of a magnetic steel.

Therefore, when the magnetic field is applied to the powder 200 that is compressed by flowing current to the N, S-pole electromagnets 501 and 502, the magnetic field extends to the upper and lower molds 300 and 400, which are magnetic bodies. Become irregular. That is, the magnetic field (300,400) formed in the powder 200 is pressurized by the influence of the upper and lower molds (300,400) of the magnetic body is expanded to form the N, S pole boundary of the completed magnet in an irregular shape.

Therefore, FIG. 7 shows a magnet manufactured by a conventional magnetic field press apparatus. As the middle part of a magnet manufactured to have N and S poles on both sides becomes irregular (indicated by a hidden line), the magnetic force of both N and S poles is increased. There was a problem that the defective product is produced different.

In addition, when a magnet having both N and S poles is cut vertically to produce a magnet having only N or S poles, the boundary of the intermediate portion is irregular, resulting in defective products being manufactured. . In other words, if the middle part of a magnet manufactured to have N and S poles on both sides is irregular (indicated by a hidden line), the middle of the magnet is cut vertically (indicated by a solid line). The poles remain, and on the contrary, some N poles remain in the cutout portion of the magnet having only the S poles. Therefore, there was a problem that a lot of defective products are generated in the manufacture of rare earth-based magnets having only N pole or S pole only.

Therefore, the present invention is invented to solve the above problems, by making the middle boundary of the N, S magnet manufactured through a manufacturing process including a magnetic field press process to be formed vertically, the magnetic force of both N, S poles An object of the present invention is to provide a magnetic field press apparatus for producing rare earth magnets, which enables the same magnet to be manufactured.

In addition, by forming a boundary of the middle of the N, S magnets manufactured through a manufacturing process including a magnetic field press process vertically, by cutting the middle of the N, S magnets vertically to form a magnet having only N pole or S pole only In the case of manufacture, there is also an object to prevent a defect that the other polarity is left in the cut portion of the N-pole magnet or S-pole magnet.

The present invention for achieving the above object,
A rare earth magnet manufacturing apparatus comprising a magnetic field press device for producing a magnetic molded body by applying a magnetic field to a rare earth alloy powder serving as a raw material of a magnet and pressing the same at a constant pressure; The magnetic field press device includes a mold frame including a magnetic field generating unit for forming a magnetic field in the direction of the north pole to the south pole including an inner filling space in which the upper and lower openings are filled, and the powder is filled in the outer side. Consists of the upper and lower molds of the non-magnetic material to compress the powder while applying a magnetic field to the powder filled in the inner filling space of the; The upper mold has a steel material which can increase the overall strength of the upper mold in the space formed by forming a space in which the upper part is opened in the upper mold while the powder is filled in the filling space. The lower mold is characterized in that the upper mold is raised from the lower portion of the filling space to the upper portion in the state in which the upper mold blocks the upper portion of the filling space to pressurize the powder.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

delete

1 is a cross-sectional view showing a magnetic field press apparatus according to a first embodiment of the present invention.

Accordingly, the magnetic field press apparatus according to the first embodiment of the present invention pressurizes to a constant pressure while applying a magnetic field to the rare earth alloy powder 5, which is a raw material of the magnet, to produce a magnet molded body.

That is, the magnetic field press apparatus of the first embodiment according to the present invention includes an inner filling space 11 in which the upper and lower openings are filled to fill the powder 5, and the magnetic field is formed in the direction of the N pole to the S pole on the outside. Non-magnetic material that compresses the powder (5) while applying a magnetic field to the mold filled with the magnetic field generating unit (2) and the powder filled in the inner filling space (11) of the mold (1) It consists of upper and lower molds 3 and 4.

The upper and lower molds 3 and 4 are provided to press the powder through lowering and raising in the state of being inserted into the upper and lower portions of the filling space 11, and the upper and lower molds 3 and 4. ) Is composed of nonmagnetic material such as stainless steel (SUS) or high strength synthetic resin.

In addition, the magnetic field generating unit 2 is composed of N, S pole electromagnets 21.22 provided on both sides so that a magnetic field can be formed in the direction of the N pole to the S pole. That is, when current flows to the N and S pole electromagnets 21 and 22 constituting the magnetic field generating unit 2, the powder compressed in the space therebetween is magnetized under the influence of the magnetic field. Therefore, the side close to the N-pole electromagnet 21 is magnetized to the N-pole and the side close to the S-pole electromagnet 22 opposite to the S-pole.

Hereinafter, the magnet manufacturing method through the magnetic field press apparatus of the first embodiment configured as described above is as follows.

Figure 2 is a process chart showing a magnet manufacturing method through the magnetic field press apparatus of the first embodiment according to the present invention.

In the magnet manufacturing method according to the present invention, as shown in Fig. 1 and 2, first, the rare earth-based alloy is dissolved and solidified and then pulverized into a powder (10) and the powder (5) A method of manufacturing a rare earth-based magnet through a magnetic field press step (20) of manufacturing a magnet molded body by applying a magnetic field to the magnetic field and sintering the magnet molded body (30);

The magnetic field press step 20 includes an inner filling space 11 in which upper and lower openings are filled to fill the powder 5, and a mold frame 1 having a magnetic field generating unit 2 outside thereof. Mold press preparation process 20a for preparing the upper and lower molds 3 and 4 of the nonmagnetic material to compress the powder 5 filled in the mold 1 and the powder between the upper and lower molds. After filling (5) to press the powder (5) through the upper and lower molds (3, 4) while applying a magnetic field to the powder (5) in the magnetic field generating unit (2b) (20b) It is characterized by consisting of).

In particular, the pressurization of the powder (5) is to press the upper and lower dies (3, 4) through the lowering and raising in the state provided with the upper and lower portions of the filling space (11).

The upper and lower molds 3 and 4 are made of a nonmagnetic material, and the magnetic field formed from the N pole to the S pole is not affected by the upper and lower molds 3 and 4, which are nonmagnetic materials. That is, in the process of applying the magnetic field to the powder 5, the upper and lower molds 3 and 4 have no influence on the magnetic field, thereby preventing the magnetic field applied to the powder 5 from expanding or becoming irregular. .

Therefore, as shown in FIG. 3, the magnet completed through the above process is formed such that the middle N and S pole boundaries (indicated by a hidden line) are vertically formed.

Therefore, since the middle boundary of the N, S magnets manufactured as described above is vertically uniformly formed, magnets having the same magnetic force on both sides of the N and S poles can be manufactured, as well as vertically cutting the middle of the N, S magnets. Thus, when manufacturing a magnet having only the N pole or the S pole, it is possible to prevent a defect in which the other polarity remains at the cut portion of the N pole magnet or the S pole magnet.

4 is a cross-sectional view showing a magnetic field press apparatus according to a second embodiment of the present invention.

Accordingly, the magnetic field press apparatus of the second embodiment according to the present invention includes an internal filling space 11 in which the upper and lower openings are filled, and the powder 5 is filled therein, and the magnetic field in the direction of the N pole to the S pole is located on the outside. Compress the powder 5 while applying a magnetic field to the mold 1 having the magnetic field generating part 2 to be formed and the powder 5 filled in the inner filling space 11 of the mold 1. It consists of upper and lower molds (3, 4) of the non-magnetic material, the upper mold (3) is provided with the upper mold to block the upper portion of the filling space in the state that the powder (5) is filled in the filling space ; The lower mold 4 is characterized in that the upper mold 3 is raised from the lower portion of the filling space 11 to the upper portion in a state in which the upper mold 3 blocks the upper portion of the filling space 11 to pressurize the powder 5. .

Accordingly, when the magnetic field is applied to the powder 5 through the magnetic field press apparatus of the second embodiment configured as described above, the powder 5 is filled in the filling space 11 constituting the mold 1. After that, the upper mold 3 is lowered to close the upper portion of the filling space 11. Next, the upper mold 3 raises the lower mold 4 from the lower portion of the filling space 11 to the upper portion in a state in which the upper mold 3 blocks the upper portion of the filling space 11 to pressurize the powder 5. Therefore, the magnet molded body may be manufactured by pressing the upper and lower molds 3 and 4.

The upper and lower molds 3 and 4 are made of a nonmagnetic material, and the magnetic field formed from the N pole to the S pole is not affected by the upper and lower molds 3 and 4, which are nonmagnetic materials. That is, in the process of applying the magnetic field to the powder 5, the upper and lower molds 3 and 4 have no influence on the magnetic field, thereby preventing the magnetic field applied to the powder 5 from expanding or becoming irregular. .

Therefore, in the magnet completed through the above process, in the magnets with N and S poles on both sides, intermediate boundary portions (indicated by hidden lines) are vertically and uniformly formed.

Therefore, as the middle boundary of the N, S magnets manufactured as described above is vertically uniformly formed, magnets having the same magnetic force on both sides of the N and S poles can be manufactured, as well as by vertically cutting the middle of the N and S magnets. When a magnet having only the N pole or the S pole is manufactured, a defect in which the other polarity remains at the cut portion of the N pole magnet or the S pole magnet can be prevented.

FIG. 5 is a cross-sectional view showing another embodiment of the magnetic field press apparatus according to the second embodiment of the present invention. In the magnetic field press apparatus of the second embodiment, an upper portion of the upper mold 4 is opened in a space. 31 is formed, and the space portion 31 is characterized in that the iron 32 is provided so as to increase the overall strength of the upper mold (3).

Therefore, since the inside of the upper die 3 is made of steel having excellent strength, the strength of the upper die 3 can be sufficiently increased to prevent the mold from being easily damaged during the pressing process.

As the periphery of the iron 32 is provided as a non-magnetic material, the magnetic field applied to the powder 5 is not affected by the iron 32 at all due to the thickness of the non-magnetic material. Therefore, the magnet formed through the magnetic field press apparatus and completed through sintering is formed such that the boundary portions (shown by the silver lines) of both N and S poles are vertically and uniformly formed.

The present invention as described above, by vertically forming the middle boundary of the N, S pole magnet manufactured through the manufacturing process including the magnetic field press process, it is possible to repeatedly repeat the magnet without uniform defects of the N, S pole magnets on both sides It will have an effect that can be produced.

In addition, by forming the intermediate boundary of the manufactured N, S pole magnet vertically, by cutting the middle of the N, S magnet vertically to prevent the occurrence of defects when manufacturing a magnet having only N pole or only S pole It also has an effect.

While the present invention has been described with reference to the accompanying drawings, it will be apparent to those skilled in the art that many various obvious modifications are possible without departing from the scope of the invention from this description. Therefore, the scope of the invention should be construed by the claims described to include many such variations.

Claims (5)

A rare earth magnet manufacturing apparatus comprising a magnetic field press apparatus for producing a magnetic molded body by applying a magnetic field to a rare earth alloy powder (5) serving as a raw material of a magnet and pressing the same at a constant pressure; The magnetic field press device, A mold frame including an internal filling space 11 in which upper and lower openings are filled to fill the powder 5, and a magnetic field generating unit 2 configured to form a magnetic field in the direction of the N pole to the S pole on the outside ( 1) and, Consists of the upper and lower molds (3, 4) of the non-magnetic material to compress the powder (5) while applying a magnetic field to the powder (5) filled in the inner filling space (11) of the mold (1); The upper mold 3 is a space formed by forming an upper portion of the upper filling space in the filling space in the state filled with the powder (5), the upper mold 31 is formed in the upper mold (3) The portion 31 is embedded with an iron material 32 that can increase the overall strength of the upper mold 3, The lower mold 4 is a rare earth-based magnet, characterized in that the upper mold 3 is raised to the upper portion from the lower portion of the filling space 11 in the state that blocked the upper portion of the filling space to press the powder (5) Magnetic field press device for manufacturing. delete delete delete delete

Images